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TRANSCRIPT
POSTERIOR
ANTERIOR
Transverse plane Sternum
Muscle
Left lung
Esophagus
Sixth thoracicvertebra
Heart
AortaView
Inferior view of transverse section of thoracic cavity showing the heart in the mediastinum
(a)
Superior vena cava Arch of aorta
Pulmonary trunk
Left lung
APEX OF HEART
Right lung
Pleura (cut toreveal lung inside)
Diaphragm
(b) Anterior view of the heart in the thoracic cavity
LEFT BORDER
SUPERIOR BORDER
RIGHT BORDER
INFERIOR SURFACE
Right lung
ANATOMY OF THE HEARTO B J E C T I V E S• Describe the location of the heart. • Describe the structure of the pericardium and the heart
wall.• Discuss the external and internal anatomy of the cham-
bers of the heart.
Location of the Heart
For all its might, the heart is relatively small, roughly the samesize (but not the same shape) as your closed fist. It is about 12 cm (5 in.) long, 9 cm (3.5 in.) wide at its broadest point, and
!
6 cm (2.5 in.) thick, with an average mass of 250 g (8 oz) inadult females and 300 g (10 oz) in adult males. The heart restson the diaphragm, near the midline of the thoracic cavity. It liesin the mediastinum (me-de-a-STI-num), an anatomical regionthat extends from the sternum to the vertebral column, the firstrib to the diaphragm, and between the lungs (Figure 20.1a).About two-thirds of the mass of the heart lies to the left of thebody’s midline (Figure 20.1b). You can visualize the heart as acone lying on its side. The pointed apex is formed by the tip ofthe left ventricle (a lower chamber of the heart) and rests on thediaphragm. It is directed anteriorly, inferiorly, and to the left.The base of the heart is its posterior surface. It is formed by theatria (upper chambers) of the heart, mostly the left atrium.
718 CHAPTER 20 • THE CARDIOVASCULAR SYSTEM: THE HEART
Figure 20.1 Position of the heart and associated structures in the mediastinum (dashed outline). (See Tortora,A Photographic Atlas of the Human Body, Second Edition, Figures 6.5 and 6.6.)
The heart is located in the mediastinum, with two-thirds of its mass to the left of the midline.
What is the mediastinum??
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POSTERIOR
ANTERIOR
Transverse plane Sternum
Muscle
Left lung
Esophagus
Sixth thoracicvertebra
Heart
AortaView
Inferior view of transverse section of thoracic cavity showing the heart in the mediastinum
(a)
Superior vena cava Arch of aorta
Pulmonary trunk
Left lung
APEX OF HEART
Right lung
Pleura (cut toreveal lung inside)
Diaphragm
(b) Anterior view of the heart in the thoracic cavity
LEFT BORDER
SUPERIOR BORDER
RIGHT BORDER
INFERIOR SURFACE
Right lung
ANATOMY OF THE HEARTO B J E C T I V E S• Describe the location of the heart. • Describe the structure of the pericardium and the heart
wall.• Discuss the external and internal anatomy of the cham-
bers of the heart.
Location of the Heart
For all its might, the heart is relatively small, roughly the samesize (but not the same shape) as your closed fist. It is about 12 cm (5 in.) long, 9 cm (3.5 in.) wide at its broadest point, and
!
6 cm (2.5 in.) thick, with an average mass of 250 g (8 oz) inadult females and 300 g (10 oz) in adult males. The heart restson the diaphragm, near the midline of the thoracic cavity. It liesin the mediastinum (me-de-a-STI-num), an anatomical regionthat extends from the sternum to the vertebral column, the firstrib to the diaphragm, and between the lungs (Figure 20.1a).About two-thirds of the mass of the heart lies to the left of thebody’s midline (Figure 20.1b). You can visualize the heart as acone lying on its side. The pointed apex is formed by the tip ofthe left ventricle (a lower chamber of the heart) and rests on thediaphragm. It is directed anteriorly, inferiorly, and to the left.The base of the heart is its posterior surface. It is formed by theatria (upper chambers) of the heart, mostly the left atrium.
718 CHAPTER 20 • THE CARDIOVASCULAR SYSTEM: THE HEART
Figure 20.1 Position of the heart and associated structures in the mediastinum (dashed outline). (See Tortora,A Photographic Atlas of the Human Body, Second Edition, Figures 6.5 and 6.6.)
The heart is located in the mediastinum, with two-thirds of its mass to the left of the midline.
What is the mediastinum??
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CVS consists of the blood , the heart and blood vessels
POSTERIOR
ANTERIOR
Transverse plane Sternum
Muscle
Left lung
Esophagus
Sixth thoracicvertebra
Heart
AortaView
Inferior view of transverse section of thoracic cavity showing the heart in the mediastinum
(a)
Superior vena cava Arch of aorta
Pulmonary trunk
Left lung
APEX OF HEART
Right lung
Pleura (cut toreveal lung inside)
Diaphragm
(b) Anterior view of the heart in the thoracic cavity
LEFT BORDER
SUPERIOR BORDER
RIGHT BORDER
INFERIOR SURFACE
Right lung
ANATOMY OF THE HEARTO B J E C T I V E S• Describe the location of the heart. • Describe the structure of the pericardium and the heart
wall.• Discuss the external and internal anatomy of the cham-
bers of the heart.
Location of the Heart
For all its might, the heart is relatively small, roughly the samesize (but not the same shape) as your closed fist. It is about 12 cm (5 in.) long, 9 cm (3.5 in.) wide at its broadest point, and
!
6 cm (2.5 in.) thick, with an average mass of 250 g (8 oz) inadult females and 300 g (10 oz) in adult males. The heart restson the diaphragm, near the midline of the thoracic cavity. It liesin the mediastinum (me-de-a-STI-num), an anatomical regionthat extends from the sternum to the vertebral column, the firstrib to the diaphragm, and between the lungs (Figure 20.1a).About two-thirds of the mass of the heart lies to the left of thebody’s midline (Figure 20.1b). You can visualize the heart as acone lying on its side. The pointed apex is formed by the tip ofthe left ventricle (a lower chamber of the heart) and rests on thediaphragm. It is directed anteriorly, inferiorly, and to the left.The base of the heart is its posterior surface. It is formed by theatria (upper chambers) of the heart, mostly the left atrium.
718 CHAPTER 20 • THE CARDIOVASCULAR SYSTEM: THE HEART
Figure 20.1 Position of the heart and associated structures in the mediastinum (dashed outline). (See Tortora,A Photographic Atlas of the Human Body, Second Edition, Figures 6.5 and 6.6.)
The heart is located in the mediastinum, with two-thirds of its mass to the left of the midline.
What is the mediastinum??
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In addition to the apex and base, the heart has several distinctsurfaces and borders (margins). The anterior surface is deep tothe sternum and ribs. The inferior surface is the part of theheart between the apex and right border and rests mostly on thediaphragm (Figure 20.1b). The right border faces the right lungand extends from the inferior surface to the base. The left bor-der, also called the pulmonary border, faces the left lung and ex-tends from the base to the apex.
Pericardium
The membrane that surrounds and protects the heart is the peri-cardium ( peri- ! around). It confines the heart to its positionin the mediastinum, while allowing sufficient freedom of move-ment for vigorous and rapid contraction. The pericardium con-sists of two main parts: (1) the fibrous pericardium and (2) theserous pericardium (Figure 20.2a). The superficial fibrous peri-cardium is composed of tough, inelastic, dense irregular con-nective tissue. It resembles a bag that rests on and attaches to thediaphragm; its open end is fused to the connective tissues of theblood vessels entering and leaving the heart. The fibrous peri-cardium prevents overstretching of the heart, provides protec-tion, and anchors the heart in the mediastinum.
The deeper serous pericardium is a thinner, more delicatemembrane that forms a double layer around the heart (Figure20.2a). The outer parietal layer of the serous pericardium isfused to the fibrous pericardium. The inner visceral layer of theserous pericardium, also called the epicardium (epi- ! on topof), is one of the layers of the heart wall and adheres tightly tothe surface of the heart. Between the parietal and visceral layersof the serous pericardium is a thin film of lubricating serousfluid. This slippery secretion of the pericardial cells, known aspericardial fluid, reduces friction between the layers of theserous pericardium as the heart moves. The space that containsthe few milliliters of pericardial fluid is called the pericardialcavity.
ANATOMY OF THE HEART 719
• CLINICAL CONNECTION CardiopulmonaryResuscitation
Because the heart lies between two rigid structures—the vertebralcolumn and the sternum (Figure 20.1a)—external pressure on the chest(compression) can be used to force blood out of the heart and into thecirculation. In cases in which the heart suddenly stops beating, cardiopul-monary resuscitation (CPR)—properly applied cardiac compressions,performed with artificial ventilation of the lungs via mouth-to-mouthrespiration—saves lives. CPR keeps oxygenated blood circulating untilthe heart can be restarted.
In a 2007 Japanese study, researchers found that chest compres-sions alone are equally as effective as, if not better than, traditional CPRwith lung ventilation. This is good news because it is easier for an emer-gency dispatcher to give instructions limited to chest compressions tofrightened, nonmedical bystanders. As public fear of contracting conta-gious diseases such as hepatitis, HIV, and tuberculosis continues torise, bystanders are much more likely to perform chest compressionsalone than treatment involving mouth-to-mouth rescue breathing. •
ENDOCARDIUM
FIBROUS PERICARDIUM
PARIETAL LAYER OF SEROUS PERICARDIUM
VISCERAL LAYER OF SEROUS PERICARDIUM (EPICARDIUM)
Pericardial cavity
(a) Portion of pericardium and right ventricular heart wall showing the divisions of the pericardium and layers of the heart wall
MYOCARDIUM(CARDIAC MUSCLE)
Trabeculae carneae
PERICARDIUMHeart wall
Coronary blood vessels
Pericardium
Epicardium
Myocardium
Endocardium
Pericardialcavity
Figure 20.2 Pericardium and heart wall.
The pericardium is a triple-layered sac that surrounds and protects the heart.
F I G U R E 20.2 CO N T I N U E S
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ANATOMY OF THE HEART 721
Figure 20.3 Structure of the heart: surface features. Throughout this book, blood vessels that carry oxygenated blood(which looks bright red) are colored red, whereas those that carry deoxygenated blood (which looks dark red)are colored blue.
Sulci are grooves that contain blood vessels and fat and mark the external boundaries between the various chambers.
Brachiocephalic trunk
Ascending aorta
Ligamentum arteriosumSuperior vena cava
RIGHT AURICLE OF RIGHT ATRIUM
RIGHT VENTRICLE
Left subclavian artery
LEFT AURICLE OF LEFT ATRIUM
Pulmonary trunk
Left pulmonary artery
Arch of aorta
Left common carotid artery
ANTERIOR INTERVENTRICULAR SULCUS
LEFT VENTRICLE
(b) Anterior external view
CORONARY SULCUS
RIGHT ATRIUM
Right pulmonary veinsLeft pulmonary veins
Descending aorta
ANTERIOR INTERVENTRICULAR SULCUS
LEFT VENTRICLE
Branch of left coronary artery
LEFT AURICLE OF LEFT ATRIUM
Pulmonary trunk
Left pulmonary arteryAscending aorta
Ligamentum arteriosumArch of aorta
Left subclavian arteryLeft common carotid artery
Left pulmonary veins
Brachiocephalic trunk
Superior vena cava
RIGHT ATRIUMCORONARY SULCUS
RIGHT VENTRICLE
Inferior vena cava
Right pulmonary artery
Right pulmonary veins
RIGHT AURICLE OF RIGHT ATRIUMRight coronary artery
Fibrous pericardium (cut)
(a) Anterior external view showing surface features
F I G U R E 20.3 CO N T I N U E S
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ANATOMY OF THE HEART 721
Figure 20.3 Structure of the heart: surface features. Throughout this book, blood vessels that carry oxygenated blood(which looks bright red) are colored red, whereas those that carry deoxygenated blood (which looks dark red)are colored blue.
Sulci are grooves that contain blood vessels and fat and mark the external boundaries between the various chambers.
Brachiocephalic trunk
Ascending aorta
Ligamentum arteriosumSuperior vena cava
RIGHT AURICLE OF RIGHT ATRIUM
RIGHT VENTRICLE
Left subclavian artery
LEFT AURICLE OF LEFT ATRIUM
Pulmonary trunk
Left pulmonary artery
Arch of aorta
Left common carotid artery
ANTERIOR INTERVENTRICULAR SULCUS
LEFT VENTRICLE
(b) Anterior external view
CORONARY SULCUS
RIGHT ATRIUM
Right pulmonary veinsLeft pulmonary veins
Descending aorta
ANTERIOR INTERVENTRICULAR SULCUS
LEFT VENTRICLE
Branch of left coronary artery
LEFT AURICLE OF LEFT ATRIUM
Pulmonary trunk
Left pulmonary arteryAscending aorta
Ligamentum arteriosumArch of aorta
Left subclavian arteryLeft common carotid artery
Left pulmonary veins
Brachiocephalic trunk
Superior vena cava
RIGHT ATRIUMCORONARY SULCUS
RIGHT VENTRICLE
Inferior vena cava
Right pulmonary artery
Right pulmonary veins
RIGHT AURICLE OF RIGHT ATRIUMRight coronary artery
Fibrous pericardium (cut)
(a) Anterior external view showing surface features
F I G U R E 20.3 CO N T I N U E S
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greater volume of blood. Also on the surface of the heart are aseries of grooves, called sulci (SUL-se), that contain coronaryblood vessels and a variable amount of fat. Each sulcus (SUL-kus) marks the external boundary between two chambers of theheart. The deep coronary sulcus (coron- ! resembling a crown)encircles most of the heart and marks the external boundary be-tween the superior atria and inferior ventricles. The anteriorinterventricular sulcus is a shallow groove on the anterior sur-face of the heart that marks the external boundary between theright and left ventricles. This sulcus continues around to the pos-terior surface of the heart as the posterior interventricularsulcus, which marks the external boundary between the ventri-cles on the posterior aspect of the heart (Figure 20.3c).
Right AtriumThe right atrium forms the right border of the heart and re-ceives blood from three veins: the superior vena cava, inferiorvena cava, and coronary sinus (Figure 20.4a) (Veins always re-turn blood to the heart). The right atrium is about 2–3 mm(0.08–0.12 in.) in average thickness. The anterior and posteriorwalls of the right atrium are very different. The posterior wall issmooth; the anterior wall is rough due to the presence of muscu-lar ridges called pectinate muscles (PEK-tin-at; pectin !comb), which also extend into the auricle (Figure 20.4b).Between the right atrium and left atrium is a thin partition called
the interatrial septum (inter- ! between; septum ! a dividingwall or partition). A prominent feature of this septum is an ovaldepression called the fossa ovalis, the remnant of the foramenovale, an opening in the interatrial septum of the fetal heart thatnormally closes soon after birth (see Figure 21.30 on page 822).Blood passes from the right atrium into the right ventriclethrough a valve that is called the tricuspid valve (trı-KUS-pid;tri- ! three; cuspid ! point) because it consists of three leafletsor cusps (Figure 20.4a). It is also called the right atrioventricu-lar valve. The valves of the heart are composed of dense con-nective tissue covered by endocardium.
Right VentricleThe right ventricle is about 4–5 mm (0.16–0.2 in.) in averagethickness and forms most of the anterior surface of the heart.The inside of the right ventricle contains a series of ridgesformed by raised bundles of cardiac muscle fibers called tra-beculae carneae (tra-BEK-u-le KAR-ne-e; trabeculae ! littlebeams; carneae ! fleshy; see Figure 20.2a). Some of the trabec-ulae carneae convey part of the conduction system of the heart,which you will learn about later in this chapter (see page 732).The cusps of the tricuspid valve are connected to tendonlikecords, the chordae tendineae (KOR-de ten-DIN-e-e; chord- !cord; tend- ! tendon), which in turn are connected to cone-shaped trabeculae carneae called papillary muscles (papill- !
722 CHAPTER 20 • THE CARDIOVASCULAR SYSTEM: THE HEART
Brachiocephalic trunk
Superior vena cavaAscending aorta
Right pulmonary artery
Right pulmonary veins
RIGHT ATRIUM
Right coronary arteryInferior vena cavaMiddle cardiac veinRIGHT VENTRICLE
Left common carotid arteryLeft subclavian artery
Arch of aorta
Descending aorta
Left pulmonary artery
AURICLE OF LEFT ATRIUMLeft pulmonary veins
LEFT ATRIUM
Coronary sinus(in the coronary sulcus)
LEFT VENTRICLE
POSTERIOR INTERVENTRICULAR SULCUS
(c) Posterior external view showing surface features
The coronary sulcus forms an external boundary between which chambers of the heart??
F I G U R E 20.3 CO N T I N U E D
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Figure 20.4 Structure of the heart: internal anatomy.
Blood flows into the right atrium through the superior vena cava, inferior vena cava, and coronary sinus and intothe left atrium through four pulmonary veins.
Left common carotid arteryLeft subclavian artery
Arch of aortaLigamentum arteriosum
Left pulmonary arteryPulmonary trunk
LEFT ATRIUMAORTIC VALVEBICUSPID (MITRAL) VALVE
CHORDAE TENDINEAE
INTERVENTRICULAR SEPTUM
PAPILLARY MUSCLE
LEFT VENTRICLE
TRABECULAE CARNEAE
Descending aorta
Left pulmonary veinsPULMONARY VALVE
Superior vena cavaAscending aorta
Brachiocephalic trunk
Inferior vena cava
RIGHT VENTRICLETRICUSPID VALVE
Opening of inferior vena cavaOpening of coronary sinusRIGHT ATRIUMFossa ovalis
Opening of superior vena cava
Right pulmonary artery
Right pulmonary veins
(a) Anterior view of frontal section showing internal anatomy
Frontal plane
Arch of aorta
Pulmonary trunk
LEFT AURICLE
TRABECULAE CARNEAE
LEFT VENTRICLE
INTERVENTRICULARSEPTUM
Pectinate muscles
RIGHT ATRIUM
RIGHT AURICLE(cut open)
Cusp of tricuspid valve
Right pulmonary vein
Ascending aorta
Chordae tendineae
Papillary muscle
RIGHT VENTRICLE
(b) Anterior view of partially sectioned heart
Superior vena cava
Brachiocephalic trunk
Left common carotid artery
Left subclavian artery
Left pulmonary vein
Ligamentum anteriosum
F I G U R E 20.4 CO N T I N U E S
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723
Figure 20.4 Structure of the heart: internal anatomy.
Blood flows into the right atrium through the superior vena cava, inferior vena cava, and coronary sinus and intothe left atrium through four pulmonary veins.
Left common carotid arteryLeft subclavian artery
Arch of aortaLigamentum arteriosum
Left pulmonary arteryPulmonary trunk
LEFT ATRIUMAORTIC VALVEBICUSPID (MITRAL) VALVE
CHORDAE TENDINEAE
INTERVENTRICULAR SEPTUM
PAPILLARY MUSCLE
LEFT VENTRICLE
TRABECULAE CARNEAE
Descending aorta
Left pulmonary veinsPULMONARY VALVE
Superior vena cavaAscending aorta
Brachiocephalic trunk
Inferior vena cava
RIGHT VENTRICLETRICUSPID VALVE
Opening of inferior vena cavaOpening of coronary sinusRIGHT ATRIUMFossa ovalis
Opening of superior vena cava
Right pulmonary artery
Right pulmonary veins
(a) Anterior view of frontal section showing internal anatomy
Frontal plane
Arch of aorta
Pulmonary trunk
LEFT AURICLE
TRABECULAE CARNEAE
LEFT VENTRICLE
INTERVENTRICULARSEPTUM
Pectinate muscles
RIGHT ATRIUM
RIGHT AURICLE(cut open)
Cusp of tricuspid valve
Right pulmonary vein
Ascending aorta
Chordae tendineae
Papillary muscle
RIGHT VENTRICLE
(b) Anterior view of partially sectioned heart
Superior vena cava
Brachiocephalic trunk
Left common carotid artery
Left subclavian artery
Left pulmonary vein
Ligamentum anteriosum
F I G U R E 20.4 CO N T I N U E S
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C H E C K P O I N T25. Describe how a heart transplant is performed.26. Explain four different cardiac arrest devices and
procedures.
DEVELOPMENT OFTHE HEART
O B J E C T I V E• Describe the development of the heart.
Listening to a fetal heartbeat for the first time is an exciting mo-ment for prospective parents, but it is also an important diagnos-tic tool. The cardiovascular system is one of the first systems toform in an embryo, and the heart is the first functional organ.
!
! This order of development is essential because of the need of therapidly growing embryo to obtain oxygen and nutrients and getrid of wastes. As you will learn shortly, the development of theheart is a complex process, and any disruptions along the waycan result in congenital (present at birth) disorders of the heart.Such disorders, described on page 752, are responsible for al-most half of all deaths from birth defects.
The heart begins its development from mesoderm on day 18or 19 following fertilization. In the head end of the embryo, theheart develops from a group of mesodermal cells called the car-diogenic area (kar-de-o-JEN-ik; cardio- ! heart; -genic ! pro-ducing) (Figure 20.19a). In response to signals from the underly-ing endoderm, the mesoderm in the cardiogenic area forms apair of elongated strands called cardiogenic cords. Shortly after,these cords develop a hollow center and then become known asendocardial tubes (Figure 20.19b). With lateral folding of the
748 CHAPTER 20 • THE CARDIOVASCULAR SYSTEM: THE HEART
Cardiogenic area
Head end
19 days
(a) Location of cardiogenic area
Neural plate
Arterial end of heart
Venous end of heart
(b) Formation of endocardial tubes
(c) Formation of primitive heart tube
(d) Development of regions in the primitive heart tube
(e) Bending of the primitive heart (f) Orientation of atria and ventricles to their final adult position
20 days 21 days 22 days
23 days 24 days 28 days
Fusion ofendocardial tubesinto primitive heart tube
Ventricle
Sinus venosus
Atrium
Atrium
Bulbus cordis
Truncusarteriosus
Bulbus cordis
Truncus arteriosus
PulmonarytrunkAtrium
AortaSuperior vena cava
Ventricle
Inferior vena cava
Ventricle
Sinusvenosus
Endocardial tubes
When during embryonic development does the primitive heart begin to contract??
Figure 20.19 Development of the heart. Arrows within the structures indicate the direction of blood flow.
The heart begins its development from a group of mesodermal cells called the cardiogenic area duringthe third week after fertilization.
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embryo, the paired endocardial tubes approach each other andfuse into a single tube called the primitive heart tube on day 21following fertilization (Figure 20.19c).
On the twenty-second day, the primitive heart tube developsinto five distinct regions and begins to pump blood. From tailend to head end (and the direction of blood flow) they are the (1)sinus venosus, (2) atrium, (3) ventricle, (4) bulbus cordis, and(5) truncus arteriosus. The sinus venosus initially receivesblood from all the veins in the embryo; contractions of the heartbegin in this region and follow sequentially in the other regions.Thus, at this stage, the heart consists of a series of unpairedregions. The fates of the regions are as follows:
1. The sinus venosus develops into part of the right atrium,coronary sinus, and sinoatrial (SA) node.2. The atrium develops into part of the right atrium, right auri-cle, and the left atrium and left auricle.3. The ventricle gives rise to the left ventricle.4. The bulbus cordis develops into the right ventricle.5. The truncus arteriosus gives rise to the ascending aorta andpulmonary trunk.
On day 23, the primitive heart tube elongates. Because thebulbus cordis and ventricle grow more rapidly than other parts ofthe tube and because the atrial and venous ends of the tube areconfined by the pericardium, the tube begins to loop and fold. Atfirst, the primitive heart tube assumes a U-shape; later it be-comes S-shaped (Figure 20.19e). As a result of these move-ments, which are completed by day 28, the atria and ventriclesof the future heart are reoriented to assume their final adult posi-tions. The remainder of heart development consists of recon-struction of the chambers and the formation of septa and valvesto form a four-chambered heart.
On about day 28, thickenings of mesoderm of the inner lining of the heart wall, called endocardial cushions, appear(Figure 20.20). They grow toward each other, fuse, and dividethe single atrioventricular canal (region between atria and ventricles) into smaller, separate left and right atrioventricularcanals. Also, the interatrial septum begins its growth towardfused endocardial cushions. Ultimately, the interatrial septumand endocardial cushions unite and an opening in the septum,the foramen ovale, develops. The interatrial septum divides the atrial region into a right atrium and a left atrium. Beforebirth, the foramen ovale allows most blood entering the rightatrium to pass into the left atrium. After birth, it normally closes so that the interatrial septum is a complete partition. Theremnant of the foramen ovale is the fossa ovalis (Figure 20.20).Formation of the interventricular septum partitions the ventric-ular region into a right ventricle and a left ventricle.Partitioning of the atrioventricular canal, atrial region, and ven-tricular region is basically complete by the end of the fifth week. The atrioventricular valves form between the fifth andeighth weeks. The semilunar valves form between the fifth andninth weeks.
C H E C K P O I N T27. Why is the cardiovascular system one of the first
systems to develop?28. From which tissue does the heart develop?
!
DEVELOPMENT OF THE HEART 749
Superiorvena cava
Futureinteratrialseptum
Ventricle
Futureinterventricularseptum
Pulmonary veins
Atrium
Atrioventricular canals
Endocardial cushion
Inferior vena cava
About 28 days
About 8 weeks
Right atrium
Tricuspid valve
Right ventricleLeft ventricle
Bicuspid valve
Foramen ovale
Left atrium
Figure 20.20 Partitioning of the heart into four chambers.
Partitioning the heart begins on about the 28th day after fertilization.
When is the partitioning of the heart complete??
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embryo, the paired endocardial tubes approach each other andfuse into a single tube called the primitive heart tube on day 21following fertilization (Figure 20.19c).
On the twenty-second day, the primitive heart tube developsinto five distinct regions and begins to pump blood. From tailend to head end (and the direction of blood flow) they are the (1)sinus venosus, (2) atrium, (3) ventricle, (4) bulbus cordis, and(5) truncus arteriosus. The sinus venosus initially receivesblood from all the veins in the embryo; contractions of the heartbegin in this region and follow sequentially in the other regions.Thus, at this stage, the heart consists of a series of unpairedregions. The fates of the regions are as follows:
1. The sinus venosus develops into part of the right atrium,coronary sinus, and sinoatrial (SA) node.2. The atrium develops into part of the right atrium, right auri-cle, and the left atrium and left auricle.3. The ventricle gives rise to the left ventricle.4. The bulbus cordis develops into the right ventricle.5. The truncus arteriosus gives rise to the ascending aorta andpulmonary trunk.
On day 23, the primitive heart tube elongates. Because thebulbus cordis and ventricle grow more rapidly than other parts ofthe tube and because the atrial and venous ends of the tube areconfined by the pericardium, the tube begins to loop and fold. Atfirst, the primitive heart tube assumes a U-shape; later it be-comes S-shaped (Figure 20.19e). As a result of these move-ments, which are completed by day 28, the atria and ventriclesof the future heart are reoriented to assume their final adult posi-tions. The remainder of heart development consists of recon-struction of the chambers and the formation of septa and valvesto form a four-chambered heart.
On about day 28, thickenings of mesoderm of the inner lining of the heart wall, called endocardial cushions, appear(Figure 20.20). They grow toward each other, fuse, and dividethe single atrioventricular canal (region between atria and ventricles) into smaller, separate left and right atrioventricularcanals. Also, the interatrial septum begins its growth towardfused endocardial cushions. Ultimately, the interatrial septumand endocardial cushions unite and an opening in the septum,the foramen ovale, develops. The interatrial septum divides the atrial region into a right atrium and a left atrium. Beforebirth, the foramen ovale allows most blood entering the rightatrium to pass into the left atrium. After birth, it normally closes so that the interatrial septum is a complete partition. Theremnant of the foramen ovale is the fossa ovalis (Figure 20.20).Formation of the interventricular septum partitions the ventric-ular region into a right ventricle and a left ventricle.Partitioning of the atrioventricular canal, atrial region, and ven-tricular region is basically complete by the end of the fifth week. The atrioventricular valves form between the fifth andeighth weeks. The semilunar valves form between the fifth andninth weeks.
C H E C K P O I N T27. Why is the cardiovascular system one of the first
systems to develop?28. From which tissue does the heart develop?
!
DEVELOPMENT OF THE HEART 749
Superiorvena cava
Futureinteratrialseptum
Ventricle
Futureinterventricularseptum
Pulmonary veins
Atrium
Atrioventricular canals
Endocardial cushion
Inferior vena cava
About 28 days
About 8 weeks
Right atrium
Tricuspid valve
Right ventricleLeft ventricle
Bicuspid valve
Foramen ovale
Left atrium
Figure 20.20 Partitioning of the heart into four chambers.
Partitioning the heart begins on about the 28th day after fertilization.
When is the partitioning of the heart complete??
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embryo, the paired endocardial tubes approach each other andfuse into a single tube called the primitive heart tube on day 21following fertilization (Figure 20.19c).
On the twenty-second day, the primitive heart tube developsinto five distinct regions and begins to pump blood. From tailend to head end (and the direction of blood flow) they are the (1)sinus venosus, (2) atrium, (3) ventricle, (4) bulbus cordis, and(5) truncus arteriosus. The sinus venosus initially receivesblood from all the veins in the embryo; contractions of the heartbegin in this region and follow sequentially in the other regions.Thus, at this stage, the heart consists of a series of unpairedregions. The fates of the regions are as follows:
1. The sinus venosus develops into part of the right atrium,coronary sinus, and sinoatrial (SA) node.2. The atrium develops into part of the right atrium, right auri-cle, and the left atrium and left auricle.3. The ventricle gives rise to the left ventricle.4. The bulbus cordis develops into the right ventricle.5. The truncus arteriosus gives rise to the ascending aorta andpulmonary trunk.
On day 23, the primitive heart tube elongates. Because thebulbus cordis and ventricle grow more rapidly than other parts ofthe tube and because the atrial and venous ends of the tube areconfined by the pericardium, the tube begins to loop and fold. Atfirst, the primitive heart tube assumes a U-shape; later it be-comes S-shaped (Figure 20.19e). As a result of these move-ments, which are completed by day 28, the atria and ventriclesof the future heart are reoriented to assume their final adult posi-tions. The remainder of heart development consists of recon-struction of the chambers and the formation of septa and valvesto form a four-chambered heart.
On about day 28, thickenings of mesoderm of the inner lining of the heart wall, called endocardial cushions, appear(Figure 20.20). They grow toward each other, fuse, and dividethe single atrioventricular canal (region between atria and ventricles) into smaller, separate left and right atrioventricularcanals. Also, the interatrial septum begins its growth towardfused endocardial cushions. Ultimately, the interatrial septumand endocardial cushions unite and an opening in the septum,the foramen ovale, develops. The interatrial septum divides the atrial region into a right atrium and a left atrium. Beforebirth, the foramen ovale allows most blood entering the rightatrium to pass into the left atrium. After birth, it normally closes so that the interatrial septum is a complete partition. Theremnant of the foramen ovale is the fossa ovalis (Figure 20.20).Formation of the interventricular septum partitions the ventric-ular region into a right ventricle and a left ventricle.Partitioning of the atrioventricular canal, atrial region, and ven-tricular region is basically complete by the end of the fifth week. The atrioventricular valves form between the fifth andeighth weeks. The semilunar valves form between the fifth andninth weeks.
C H E C K P O I N T27. Why is the cardiovascular system one of the first
systems to develop?28. From which tissue does the heart develop?
!
DEVELOPMENT OF THE HEART 749
Superiorvena cava
Futureinteratrialseptum
Ventricle
Futureinterventricularseptum
Pulmonary veins
Atrium
Atrioventricular canals
Endocardial cushion
Inferior vena cava
About 28 days
About 8 weeks
Right atrium
Tricuspid valve
Right ventricleLeft ventricle
Bicuspid valve
Foramen ovale
Left atrium
Figure 20.20 Partitioning of the heart into four chambers.
Partitioning the heart begins on about the 28th day after fertilization.
When is the partitioning of the heart complete??
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